Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study

We present an integrated 2D model of thermal and microbial generation of methane, migration into the gas hydrate stability zone (HSZ), and formation of methane hydrates. The model reconstructs the shallow (0e20 km) thermal structure of the subduction interface between the Australian plate and the su...

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Published in:Marine and Petroleum Geology
Main Authors: Kroeger, K. J., Plaza-Faverola, A., Barnes, P. M., Pecher, I. A.
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2015
Subjects:
New Zealand
Pacific
Methane hydrate
Online Access:https://oceanrep.geomar.de/id/eprint/33504/
https://oceanrep.geomar.de/id/eprint/33504/1/Kroeger.pdf
https://doi.org/10.1016/j.marpetgeo.2015.01.020
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record_format openpolar
spelling ftoceanrep:oai:oceanrep.geomar.de:33504 2023-05-15T17:11:49+02:00 Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study Kroeger, K. J. Plaza-Faverola, A. Barnes, P. M. Pecher, I. A. 2015 text https://oceanrep.geomar.de/id/eprint/33504/ https://oceanrep.geomar.de/id/eprint/33504/1/Kroeger.pdf https://doi.org/10.1016/j.marpetgeo.2015.01.020 en eng Elsevier https://oceanrep.geomar.de/id/eprint/33504/1/Kroeger.pdf Kroeger, K. J., Plaza-Faverola, A., Barnes, P. M. and Pecher, I. A. (2015) Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study. Marine and Petroleum Geology, 63 . pp. 97-114. DOI 10.1016/j.marpetgeo.2015.01.020 <https://doi.org/10.1016/j.marpetgeo.2015.01.020>. doi:10.1016/j.marpetgeo.2015.01.020 info:eu-repo/semantics/restrictedAccess Article PeerReviewed 2015 ftoceanrep https://doi.org/10.1016/j.marpetgeo.2015.01.020 2023-04-07T15:26:56Z We present an integrated 2D model of thermal and microbial generation of methane, migration into the gas hydrate stability zone (HSZ), and formation of methane hydrates. The model reconstructs the shallow (0e20 km) thermal structure of the subduction interface between the Australian plate and the subducting Pacific plate, and the trench basin (Pegasus Basin). Modelled temperatures of less than 110 °C within Pegasus Basin constrain the generation of oil and gas. Whilst a cool thermal regime is predicted to limit thermogenic generation of gas to a burial depth of >10 km, it extends the interval where prolific microbial gas generation occurs. The modelled rate of microbial generation of methane increases beneath the HSZ and peaks at ~1600 m below seafloor. Diffusive upward migration of microbially generated methane is interpreted to lead to widespread methane hydrate formation and the presence of a semicontinuous bottom simulating reflector (BSR). Predicted average hydrate saturation within the HSZ is 0.9% for a modelled sedimentary organic matter content of 0.5% and 1.6% for 1% organic matter in finegrained Pegasus Basin sediments. Considerably higher concentrations of methane hydrate of up to 20 e70% are predicted to occur where gas migration is focussed within the frontal anticline and proto-thrust zone southeast of the modern accretionary wedge and in channel and basin floor sandstones related to the Hikurangi Channel. The Hikurangi Channel sedimentary system transported coarse clastic sediments eroded from the rising Southern Alps along the eastern margin of the Pegasus Basin since the Miocene. It provides carrier beds specifically for transport of thermogenic gas generated close to the subduction interface. A buried Mesozoic accretionary wedge originating from subduction of the Pacific Plate beneath Gondwana further focusses the migration of gas. Focussed migration of thermogenic gas leads to the highest predicted hydrate concentrations in potential channel sand reservoirs. Article in Journal/Newspaper Methane hydrate OceanRep (GEOMAR Helmholtz Centre für Ocean Research Kiel) New Zealand Pacific Marine and Petroleum Geology 63 97 114
institution Open Polar
collection OceanRep (GEOMAR Helmholtz Centre für Ocean Research Kiel)
op_collection_id ftoceanrep
language English
description We present an integrated 2D model of thermal and microbial generation of methane, migration into the gas hydrate stability zone (HSZ), and formation of methane hydrates. The model reconstructs the shallow (0e20 km) thermal structure of the subduction interface between the Australian plate and the subducting Pacific plate, and the trench basin (Pegasus Basin). Modelled temperatures of less than 110 °C within Pegasus Basin constrain the generation of oil and gas. Whilst a cool thermal regime is predicted to limit thermogenic generation of gas to a burial depth of >10 km, it extends the interval where prolific microbial gas generation occurs. The modelled rate of microbial generation of methane increases beneath the HSZ and peaks at ~1600 m below seafloor. Diffusive upward migration of microbially generated methane is interpreted to lead to widespread methane hydrate formation and the presence of a semicontinuous bottom simulating reflector (BSR). Predicted average hydrate saturation within the HSZ is 0.9% for a modelled sedimentary organic matter content of 0.5% and 1.6% for 1% organic matter in finegrained Pegasus Basin sediments. Considerably higher concentrations of methane hydrate of up to 20 e70% are predicted to occur where gas migration is focussed within the frontal anticline and proto-thrust zone southeast of the modern accretionary wedge and in channel and basin floor sandstones related to the Hikurangi Channel. The Hikurangi Channel sedimentary system transported coarse clastic sediments eroded from the rising Southern Alps along the eastern margin of the Pegasus Basin since the Miocene. It provides carrier beds specifically for transport of thermogenic gas generated close to the subduction interface. A buried Mesozoic accretionary wedge originating from subduction of the Pacific Plate beneath Gondwana further focusses the migration of gas. Focussed migration of thermogenic gas leads to the highest predicted hydrate concentrations in potential channel sand reservoirs.
format Article in Journal/Newspaper
author Kroeger, K. J.
Plaza-Faverola, A.
Barnes, P. M.
Pecher, I. A.
spellingShingle Kroeger, K. J.
Plaza-Faverola, A.
Barnes, P. M.
Pecher, I. A.
Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study
author_facet Kroeger, K. J.
Plaza-Faverola, A.
Barnes, P. M.
Pecher, I. A.
author_sort Kroeger, K. J.
title Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study
title_short Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study
title_full Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study
title_fullStr Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study
title_full_unstemmed Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study
title_sort thermal evolution of the new zealand hikurangi subduction margin: impact on natural gas generation and methane hydrate formation – a model study
publisher Elsevier
publishDate 2015
url https://oceanrep.geomar.de/id/eprint/33504/
https://oceanrep.geomar.de/id/eprint/33504/1/Kroeger.pdf
https://doi.org/10.1016/j.marpetgeo.2015.01.020
geographic New Zealand
Pacific
geographic_facet New Zealand
Pacific
genre Methane hydrate
genre_facet Methane hydrate
op_relation https://oceanrep.geomar.de/id/eprint/33504/1/Kroeger.pdf
Kroeger, K. J., Plaza-Faverola, A., Barnes, P. M. and Pecher, I. A. (2015) Thermal evolution of the New Zealand Hikurangi subduction margin: Impact on natural gas generation and methane hydrate formation – a model study. Marine and Petroleum Geology, 63 . pp. 97-114. DOI 10.1016/j.marpetgeo.2015.01.020 <https://doi.org/10.1016/j.marpetgeo.2015.01.020>.
doi:10.1016/j.marpetgeo.2015.01.020
op_rights info:eu-repo/semantics/restrictedAccess
op_doi https://doi.org/10.1016/j.marpetgeo.2015.01.020
container_title Marine and Petroleum Geology
container_volume 63
container_start_page 97
op_container_end_page 114
_version_ 1766068583127842816

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